Stroke is a leading global health concern, with cerebral infarction accounting for 62% of cases. Despite advances in acute-phase treatments, functional impairments such as motor deficits remain prevalent. This study investigates the potential of human induced pluripotent stem cell (iPSC)-derived cerebral cortical neurons for neural regeneration and motor function recovery in a female mouse model of ischemic stroke.
Cerebral infarction was induced using the Rose Bengal photothrombosis method, followed by transplantation of iPSC-derived cortical neurons into the area adjacent to the infarction. Behavioral recovery was assessed using the foot fault and cylinder tests. Histological analysis was performed to evaluate graft integration and neurite extension.
Foot fault test demonstrated significant improvements in fine motor function in the transplantation group compared to the vehicle group. However, no recovery was observed in the cylinder test, which assesses gross motor function. Neurite extension from grafted cells was observed along the corticospinal tract, with axonal projections reaching the spinal cord in 68% of transplanted mice. In addition, neurite outgrowth extended to the thalamus, superior colliculus, and vestibular nucleus, suggesting integration into multiple neural circuits. Histological analysis revealed that 16.4% and 47.3% of grafted cells expressed CTIP2 and SATB2, respectively, indicating the presence of both deep- and upper-layer cortical neurons.
This study demonstrates that iPSC-derived cortical neurons extend axons along the corticospinal tract and can promote fine motor recovery after stroke. However, further research is needed to validate functional connectivity and long-term safety. These findings offer a promising avenue for developing cell-based therapies for stroke patients.
© 2025. The Author(s).

Thyroid carcinoma represents the first malignancy among the endocrine organs. Investigating the cellular hierarchy and the mechanisms underlying the initiation of thyroid carcinoma is crucial in thyroid cancer research. Here, we present a protocol for deriving thyroid cell lineage from human embryonic stem cells. We also describe steps for engineering thyroid progenitor cells utilizing CRISPR-Cas9 technology, which can be used to perform in vivo studies, thus facilitating the development of representative thyroid tumorigenesis models. For complete details on the use and execution of this protocol, please refer to Veschi et al.1.
Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.

Mucopolysaccharidoses are inherited metabolic disorders caused by the deficiency in lysosomal enzymes required to break down glycosaminoglycans. Accumulation of glycosaminoglycans leads to progressive, systemic degenerative disease. The central nervous system is particularly affected, resulting in developmental delays, neurological regression, and early mortality. Current treatments fail to adequately address neurological defects. Here we explore the potential of human induced pluripotent stem cell (hiPSC)-derived microglia progenitors as a one-time, allogeneic off-the-shelf cell therapy for several mucopolysaccharidoses (MPS). We show that hiPSC-derived microglia progenitors, possessing normal levels of lysosomal enzymes, can deliver functional enzymes into four subtypes of MPS knockout cell lines through mannose-6-phosphate receptor-mediated endocytosis in vitro. Additionally, our findings indicate that a single administration of hiPSC-derived microglia progenitors can reduce toxic glycosaminoglycan accumulation and prevent behavioral deficits in two different animal models of MPS. Durable efficacy is observed for eight months after transplantation. These results suggest a potential avenue for treating MPS with hiPSC-derived microglia progenitors.
© 2024. The Author(s).

Although current stem cell therapies exhibit promising potential, the extended process of employing autologous cells and the necessity for donor-host matching to avert the rejection of transplanted cells significantly limit the widespread applicability of these treatments. It would be highly advantageous to generate a pluripotent universal donor stem cell line that is immune-evasive and, therefore, not restricted by the individual's immune system, enabling unlimited application within cell replacement therapies. Before such immune-evasive stem cells can be moved forward to clinical trials, in vivo testing via transplantation experiments in immune-competent animals would be a favorable approach preceding preclinical testing. By using human stem cells in immune competent animals, results will be more translatable to a clinical setting, as no parts of the immune system have been altered, although in a xenogeneic setting. In this way, immune evasiveness, cell survival, and unwanted proliferative effects can be assessed before clinical trials in humans. The current study presents the generation and characterization of three human embryonic stem cell lines (hESCs) for xenogeneic transplantation in immune-competent mice. The major histocompatibility complexes I- and II-encoding genes, B2M and CIITA, have been deleted from the hESCs using CRISPR-Cas9-targeted gene replacement strategies and knockout. B2M was knocked out by the insertion of murine CD47. Human-secreted embryonic alkaline phosphatase (hSEAP) was inserted in a safe harbor site to track cells in vivo. The edited hESCs maintained their pluripotency, karyotypic normality, and stable expression of murine CD47 and hSEAP in vitro. In vivo transplantation of hESCs into immune-competent BALB/c mice was successfully monitored by measuring hSEAP in blood samples. Nevertheless, transplantation of immune-evasive hESCs resulted in complete rejection within 11 days, with clear immune infiltration of T-cells on day 8. Our results reveal that knockout of B2M and CIITA together with species-specific expression of CD47 are insufficient to prevent rejection in an immune-competent and xenogeneic context.
Copyright © 2024 Frederiksen, Glantz, Vøls, Skov, Tveden-Nyborg, Freude and Doehn.

To produce abundant cell culture samples to generate large, standardized image datasets of human induced pluripotent stem (hiPS) cells, we developed an automated workflow on a Hamilton STAR liquid handler system. This was developed specifically for culturing hiPS cell lines expressing fluorescently tagged proteins, which we have used to study the principles by which cells establish and maintain robust dynamic localization of cellular structures. This protocol includes all details for the maintenance, passage and seeding of cells, as well as Matrigel coating of 6-well plastic plates and 96-well optical-grade, glass plates. We also developed an automated image-based hiPS cell colony segmentation and feature extraction pipeline to streamline the process of predicting cell count and selecting wells with consistent morphology for high-resolution three-dimensional (3D) microscopy. The imaging samples produced with this protocol have been used to study the integrated intracellular organization and cell-to-cell variability of hiPS cells to train and develop deep learning-based label-free predictions from transmitted-light microscopy images and to develop deep learning-based generative models of single-cell organization. This protocol requires some experience with robotic equipment. However, we provide details and source code to facilitate implementation by biologists less experienced with robotics. The protocol is completed in less than 10 h with minimal human interaction. Overall, automation of our cell culture procedures increased our imaging samples' standardization, reproducibility, scalability and consistency. It also reduced the need for stringent culturist training and eliminated culturist-to-culturist variability, both of which were previous pain points of our original manual pipeline workflow.
© 2023. Crown.